Pneumatic method and apparatus for nano imprint lithography having a conforming mask

ABSTRACT

An apparatus for nano lithography includes a mask having a pattern formed thereon and a pneumatic pressure driving source for applying a pneumatic pressure to at least one of a surface of the mask and a surface of a workpiece, thereby to uniformly transfer the pattern from the mask to the workpiece.

The present Application is a Continuation of U.S. patent applicationSer. No. 10/989,078, filed on Nov. 16, 2004, the entire contents ofwhich is incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to a method and apparatus fornano imprint lithography, and more particularly to a pneumatic methodand apparatus for nano imprint lithography.

2. Description of the Related Art

The process of imprint lithography involves pressing a template (or moldor mask) against a polymer or photoresist-coated workpiece, curing thepolymer and removing the template from the workpiece leaving behind animpression of the template in the cured polymer coating. The deformationof the template and/or workpiece under applied mechanical pressure is aproblem when the features of the template are of very small (e.g.,nanometer) dimensions and for which it is desirable to maintain longrange dimensional tolerances on this scale.

Additionally, imperfections with respect to flatness (e.g., uniformthickness) of either the template or workpiece impose furtherconstraints to printing nanometer-scale features.

The conventional methods and apparatus have used a rigid, thick glass orquartz template rigidly clamped (or glued rigidly) to a frame.

Finally, it is desirable to use a template that is a fraction of thedimension of the workpiece or substrate in order to meet alignment andtemplate fabrication needs relating to nano scale lithography. Thus, thetemplate is applied sequentially or stepped across the substrate to fillthe substrate with patterns.

Thus, imprint lithography typically transfers a pattern from a thickblock of quartz to a generally thinner workpiece, like a silicon wafer.However, as alluded to above, when performing imprint lithography, oneattempts (ideally) to squeeze a liquid photoresist to an infinitely thinlayer except for the feature(s) etched in the mask. Silicon wafers with“real world” chips (particularly after they have been processed) havesome topography (e.g., hills and valleys on a long scale), and the chipsmay be slightly warped, etc. Thus, the silicon wafers typically are notperfectly flat. This is problematic.

Prior to the present invention, there has been no attempt to solve sucha problem by using a transparent quartz template pressed in placeagainst a workpiece using pneumatic pressure.

More specifically, there has been no apparatus or method in whichpneumatic pressure is uniformly applied against either (or both) thequartz template and the workpiece to achieve uniform compression of thephotoresist.

Hence, such methods have not been able to retain the essentialtransparent properties of the quartz template while applying uniformpressure to a conformal membrane, thereby allowing the compensation forplanarity defects in both template and workpiece.

Other conventional methods have used a template made out of a flexiblepolymer material for the purpose of providing mechanical conformitybetween template and workpiece. Still other conventional methods haveused a rigid quartz template, covered with a layer of soft polymermaterial. These methods have several major drawbacks, including thatdimensional integrity in the plane of the template is not sufficientlypreserved. Additionally, the motion of the polymer material due tonon-uniform pressure or due to small temperature gradients generatedistortions to the printed patterns that prohibit their use inmicroelectronic lithography.

While thermal curing is an option, there has been no conventional methodwhich has adequately addressed the case (and the attendant problems)where the polymer is cured by exposure to ultraviolet light (UV).Additionally, ultraviolet (UV) transparency is severely degraded by thepolymer material. Further, exposure to UV radiation degrades the polymermaterial over time.

SUMMARY OF THE INVENTION

In view of the foregoing and other exemplary problems, drawbacks, anddisadvantages of the conventional methods and structures, an exemplaryfeature of the present invention is to provide a method and structure inwhich pneumatic pressure is uniformly applied against either (or both) asemi-rigid template and a workpiece to achieve uniform compression of aphotoresist.

Another feature is to provide a method and apparatus for retaining theessential transparent properties of a template (e.g., a quartztemplate), while applying uniform pressure to a conformal membrane,thereby allowing compensation for planarity defects in both template andworkpiece.

Another feature is to retain a high degree of fidelity in the dimensionsof the printed pattern, owing to the rigid properties of the template(e.g., a quartz template) and workpiece in the pattern plane (or X-Y, orhorizontal plane). In the invention, preferably the template is a rigidmaterial such as quartz, but is thin enough to have a slight flexibilityin the surface normal dimension. In typical cases, this flexibility ison the order of microns.

In a first exemplary aspect of the present invention, a method (andapparatus) for nano lithography, includes applying a pneumatic pressureto at least one of a surface of a semi-rigid mask or template and aportion of a surface of a resist-coated workpiece, and, by the applyingof the pneumatic pressure, pressing a liquid or gelatinous polymerbetween the template and the workpiece, curing the polymer and therebytransferring a pattern from the mask to the workpiece.

In a second exemplary embodiment of the present invention, a method ofuniformly applying a force to a surface of a mask for nano-lithography,includes applying a force to a surface of a mask to uniformly transfer apattern formed on the mask, to a surface of the workpiece formedadjacent to the mask, wherein one of the mask and the workpiece isconformal.

In a third exemplary embodiment of the present invention, an apparatusfor nano lithography, includes a mask having a pattern formed thereon,and a pneumatic pressure driving source for applying a pneumaticpressure to at least one of a surface of the mask and a surface of aworkpiece, thereby to uniformly transfer the pattern from the mask tothe workpiece.

In a fourth exemplary embodiment of the present invention, an apparatusfor nano lithography, includes a mask having a pattern formed thereon,and a unit for applying a pneumatic pressure to at least one of asurface of a mask and a surface of a workpiece, to transfer the patternfrom the mask to the workpiece.

With the unique and unobvious aspects of the invention, uniformpneumatic pressure can be applied against either or both the templateand the work piece to achieve uniform compression of the photoresist.

Hence, a template with a high degree of flatness such as a rigid thickquartz mask, as well as a workpiece with a high degree of flatness (suchas a silicon wafer on a rigid holder (or chuck), both with a very highdegree of flatness and cleanliness of all surfaces) are not required.These requirements in mechanical tolerances would otherwise be veryexpensive to manage and to retain. Rather, either the template or theworkpiece is given a small degree of flexibility to accommodate smallbendings (e.g., typically in the sub-micron range) over large dimensions(e.g., typically on the scale of a centimeter), i.e., it is still stiffbut somewhat conformal. Pneumatic pressure applied to the back side ofthe template and/or the workpiece presses them together with a highdegree of conformality.

Hence, a rigid thick quartz mask rigidly clamped or glued rigidly to aframe, as in the conventional methods, is not required. The template canbe held in place until pressed by vacuum. Instead, the inventionprovides the mask with a degree of conformality (e.g., the mask is stillstiff but somewhat conformal, and then pressurizes the mask from theback side thereof, such that the mask can be pressed against the wafer(or vice versa) and get the mask to conform to the wafer.Simplistically, the inventive technique can be analogized to an innertube of a tire which, when pressurized, conforms to the inside of thetire wall (if the inner tube could be made out of aluminum foil, forexample).

The reason that the conformality is important is that, in imprintlithography, everything is exposed (e.g., with ultraviolet rays, etc.),such that the resist in the channels in the mask will harden, as well asany photoresist between the unpatterned portions of the mask and thesurface. This latter portion of resist, called the resistual layer, mustbe kept as thin as possible, and on the order of the smallest printedpattern dimension (e.g., approximately 50 nanometers in today'sapparatus). In the present art of imprint patterning, an otherwise thickresidual layer distorts the next lithographic process which transfersthe pattern in the resist into actual features (e.g., such as metallines or semiconducting regions) in the silicon wafer.

Other advantages of the present invention include that expensivemechanical tolerances can be avoided in obtaining flatness of allsurfaces.

Further, high dimensional fidelity can be maintained in the lateraldirections (in the plane of the pattern).

Additionally, the invention provides the ability to imprint overpre-patterned, non-flat wafers.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and other exemplary purposes, aspects and advantages willbe better understood from the following detailed description ofexemplary embodiments of the invention with reference to the drawings,in which:

FIG. 1 illustrates a pneumatic membrane imprint lithography apparatus100 according to the present invention;

FIG. 2A illustrates a pneumatic membrane imprint lithography apparatus200 according to a second embodiment of the present invention;

FIG. 2B illustrates a pneumatic membrane imprint lithography apparatus290 according to a third embodiment of the present invention usingpartial vacuum and atmospheric pressure; and

FIG. 3 illustrates a method 300 of nano imprint lithography according tothe present invention.

DETAILED DESCRIPTION OF EXEMPLARY Embodiments of the Invention

Referring now to the drawings, and more particularly to FIGS. 1-3, thereare shown exemplary embodiments of the method and structures accordingto the present invention.

Exemplary Embodiment

As mentioned above, imprint lithography refers to a process where atemplate or mold containing a pattern is pressed against a workpiecewith a layer of intervening photoresist. As the photoresist iscompressed between the template and the workpiece, the photoresistspreads out and fills the space between the template and the workpieceand the patterned voids in the template.

At the desired distance between template and workpiece, the photoresistis cured by exposure to UV light through the transparent template. Oncethe resist is cured, the template is removed, thereby leaving behind thetemplate pattern in the cured photoresist covering the workpiece. Thus,the template pattern has been transferred to the workpiece.

During the compression phase of this process, it is critical to avoiddistortions of both the template and workpiece.

To achieve the printing of nanometer-scale features, the template shouldhave uniform pressure. As mentioned above, this is typically resolvedusing thick quartz to disperse the mechanical pressure applied to hardpoint mounts. Departure from perfect flatness in either the template orworkpiece further compounds the problem of transferring small featuresacross the field.

Turning now to FIG. 1, the present invention resolves the above andother problems of the conventional methods by providing an apparatus 100which uses a thin transparent membrane 110 as the lithographic patterntemplate.

The membrane 110 is preferably patterned on one side, and is preferablythin enough to be flexible on a desired dimension scale. For example,the membrane 110 may have a thickness within a range of about 50 micronsto about 500 microns which is useful in quartz. Different stiffnessvalues can be achieved by varying this parameter. It is noted that themask can be made of materials other than quartz such as, for example,sapphire. The essential quality is that the mask be hard, rigid andthinned to the point where it is flexible on the order of microns in thenormal direction.

The membrane 110 is preferably formed of a material chosen to betransparent to the radiation (e.g., actinic wavelengths) necessary toexpose/activate the photoresist 130, but also, generally, transparent tovisible wavelengths so that optical alignment can be performed of thepattern on the mask with the underlying workpiece 120. That is, the usershould be able to optically image through the mask/membrane 110 in thealignment process.

The membrane 110 may be held by a pressure seal 140 preferably formed ofviton or similar material.

The pressure seal 140 includes an air pressure inlet 145 for receivingan air pressure from a pneumatic pressure source. Instead of air, anygas may be used such as nitrogen, helium or the like. The inlet may havea diameter within a range of millimeters.

As shown, the membrane 110 is mounted to a transparent rigid window 150,and forms a predetermined gap 146 between a lower surface of the window150 and the upper surface of the membrane 110. The window is preferablyoptically perfect (i.e., surface roughness on the order of preferably nomore than about 30 nm) and preferably is formed of flat quartz materialor the like.

The gap 146 preferably has a thickness in excess of dimensions thatwould cause optical fringes (e.g., a millimeter or so) but as would beevident the thickness of the gap depends upon the designer's constraintsand requirements such as the composition (e.g., material and thickness)of the membrane and the amount of pressure being input to the gap tomake the membrane conformal. The gap should be large enough so thatetalon fringes and the like are avoided.

The window 150 is coupled (e.g., fastened) to a mounting flange 160 of apositioning mechanism (not shown). By virtue of the window 150 beingtransparent to the curing wavelength, one can still image through thetransparent window, and still get radiation therethrough and through themembrane 110 to image and form the pattern onto the workpiece 120.

The membrane/template 110 is positioned over the desired location on aworkpiece 120, lowered mechanically to close proximity to the work piece(or light contact therewith) and pneumatic pressure is applied againstthe back side (e.g., in FIG. 1, the surface of the membrane opposing thelower surface of the transparent rigid window 150) of themembrane/template 110 causing it to be pressed into a photoresist 130uniformly. Small variations in the flatness of the workpiece 120 arecompensated by the flexure of the membrane 110, thereby resulting in auniform application of the membrane/template 110. When the workpiece 120itself is compliant (e.g., a thin silicon wafer), this strategy cancompensate for compliance of the workpiece 120 with respect to apositioning chuck (not shown in FIG. 1).

In operation, the apparatus 100 of FIG. 1 picks up a mask/membrane 110,and moves the mask/membrane 110 over the workpiece. Then, themask/membrane 110 is mechanically lowered against the workpiece 120 aspneumatic pressure is applied to the membrane 110. Alternatively, theworkpiece 120 could be raised against the membrane 110 while pneumaticpressure is applied.

Hence, the inventive method uniformly applies pneumatic pressure againsteither (or both) the template 110 and the workpiece 120 to achieveuniform compression of the photoresist 130.

For example, FIG. 2A illustrates a pneumatic membrane imprintlithography apparatus 200 according to a second embodiment of thepresent invention, in which pressure is applied to the backside of aflexible workpiece 220 (e.g., a silicon wafer). The workpiece has aphotoresist 230 formed thereon.

The apparatus 200 uses a transparent window 250 with an etch pattern(mold) thereon as the lithographic pattern template. The transparentwindow is mounted to a mounting flange 260, and is opposed to theflexible workpiece 220.

The window 250 is preferably formed of a material chosen to betransparent to the radiation (e.g., actinic wavelengths) necessary toexpose/activate the photoresist 230, but also, generally, transparent tovisible wavelengths so that optical alignment can be performed of thepattern on the mask with the underlying workpiece 220. That is, the usershould be able to look (image) through the window 250 in the alignmentprocess.

The workpiece 220 may be held (or contacted) by a rubber seal 240 (orflexible skirt or small gap).

The rubber seal 240 is coupled to a housing structure 255 which includesan air pressure inlet 245 for receiving an air pressure from a pneumaticpressure source. Instead of air, as in the first embodiment, any gas maybe used such as nitrogen, helium or the like. The inlet may have adiameter that is small, since the amount of gas flow is small.

As shown, the structure of the rubber seal 240/housing 255 forms apredetermined gap 246 which is formed between a lower surface of theworkpiece 220 and the interior surface of the housing 255.

As before, the window 250 is preferably optically perfect and preferablyis formed of flat quartz material or the like.

The gap 246 preferably has a thickness within millimeter range but aswould be evident the thickness of the gap depends upon the designer'sconstraints and requirements such as the composition (e.g., material andthickness) of the membrane and the amount of pressure being input to thegap to make the membrane conformal.

The template 250 is coupled (e.g., fastened) to a mounting flange 260 ofa positioning mechanism (not shown). By virtue of the window 250 beingtransparent to the curing wavelength, one can still image through thetransparent window, and still get radiation therethrough and to imageand form the pattern onto the workpiece 220.

Both upper and lower portions of the apparatus shown in FIG. 2A arepositioned at the desired location on a workpiece 220, brought intocontact with the workpiece and pneumatic pressure is applied against theback side of the workpiece 220 (e.g., in FIG. 2A, the surface of theworkpiece opposite the surface of the workpiece which has thephotoresist 230 on it), causing the window 250 to apply the pattern tothe photoresist 230 uniformly. Small variations in the flatness of theworkpiece 220 (or the window 250) are compensated by the flexure of thewafer 220, thereby resulting in a uniform application of the of thepattern to the photoresist 230. Thus, when the workpiece 220 iscompliant (e.g., a thin silicon wafer), this strategy can compensate forcompliance of the workpiece 220 with respect to a positioning chuck (notshown in FIG. 2A).

Thus, the membrane (e.g., in FIG. 1) and/or the workpiece (e.g., shownin FIG. 2A) may have a backside pressure applied thereto.

Additionally, FIG. 2B illustrates a pneumatic membrane imprintlithography apparatus 290 according to a third embodiment of the presentinvention using partial vacuum and atmospheric pressure.

Specifically, the apparatus 290 is somewhat similar to that shown inFIG. 2A, but includes a mounting flange 291 having air conduits 292formed therein. The air conduits 292 are coupled to a vacuum connection293 via an inlet 245. An atmospheric pressure 294 is applied against thebackside of the flexible workpiece 220. A partial vacuum 295 existsbetween the window 250 and the photoresist 230.

It is noted that in all three exemplary cases, it is intended that theworkpiece can be positioned relative to the template so as to be able toprint multiple impressions of the template on the workpiece in differentlocations (i.e., print a stepped pattern such as chip patterns on asemiconductor wafer).

Turning to FIG. 3, a flowchart of the inventive method 300 of nanolithography is shown.

In step 310, a pneumatic pressure is applied to at least one of asurface of a mask and a surface of a workpiece.

Then, in step 320, by virtue of the pressure applied in step 310, apattern is transferred from the mask to the workpiece.

Thus, in contrast to the conventional methods which use a rigid thickquartz mask rigidly clamped or glued rigidly to a frame, the inventivemethod retains the essential transparent properties of the quartztemplate while applying uniform pressure to a conformal membrane,thereby allowing compensation for planarity defects in both template andworkpiece.

Further, in the inventive design, it is possible to image through thetransparent window (e.g., for alignment etc.) and also to input theradiation therethrough, and thus the inventive design allows exposure ofthe resist and applying pressure to the resist at the same time.

It is noted that the invention can also be run in reverse such that themask can be picked up by an under-vacuum. Thus, if the user desires tochange masks, then the pressure can be reversed, and a new mask can bepicked up.

It is also noted that the mask/membrane 110 is laterally confined by theinventive apparatus, such that the mask 110 can be picked up undervacuum pressure, moved over to the workpiece 120, lowered onto theworkpiece, and then back pressure is applied to imprint the pattern ontothe workpiece 120, and then to lift the mask up again, vacuum pressureis applied to pull the mask 110 off the workpiece 120.

While the invention has been described in terms of several exemplaryembodiments, those skilled in the art will recognize that the inventioncan be practiced with modification within the spirit and scope of theappended claims.

Further, it is noted that, Applicant's intent is to encompassequivalents of all claim elements, even if amended later duringprosecution.

1. An apparatus for nano lithography, comprising: a mask having apattern formed thereon; and a pneumatic pressure driving source forapplying a pneumatic pressure to at least one of a surface of the maskand a surface of a workpiece, thereby to uniformly transfer the patternfrom the mask to the workpiece.
 2. The apparatus according to claim 1,wherein said mask is transparent to radiation for exposing a photoresistformed on said workpiece, thereby allowing said radiation to passthrough said mask and cure said photoresist.
 3. An apparatus for nanolithography, comprising: a mask having a pattern formed thereon; andmeans for applying a pneumatic pressure to at least one of a surface ofa mask and a surface of a workpiece, to transfer the pattern from themask to the workpiece.